Renalase inhibition regulates ß cell metabolism to defend against acute and chronic stress.

Renalase (Rnls), annotated as an oxidase enzyme, is a GWAS gene associated with Type 1 Diabetes (T1D) risk. We previously discovered that Rnls inhibition delays diabetes onset in mouse models of T1D in vivo , and protects pancreatic ß cells against autoimmune killing, ER and oxidative stress in vitro . The molecular biochemistry and functions of Rnls are entirely uncharted. Here we find that Rnls inhibition defends against loss of ß cell mass and islet dysfunction in chronically stressed Akita mice in vivo . We used RNA sequencing, untargeted and targeted metabolomics and metabolic function experiments in mouse and human ß cells and discovered a robust and conserved metabolic shift towards glycolysis, amino acid abundance and GSH synthesis to counter protein misfolding stress, in vitro . Our work illustrates a function for Rnls in mammalian cells, and suggests an axis by which manipulating intrinsic properties of ß cells can rewire metabolism to protect against diabetogenic stress.

Protective Renalase Deficiency in ß-Cells Shapes Immune Metabolism and Function in Autoimmune Diabetes.

Type 1 diabetes (T1D) is caused by the immune-mediated loss of pancreatic ß-cells that produce insulin. The latest advances in stem cell (SC) ß-cell differentiation methods have made a cell replacement therapy for T1D feasible. However, recurring autoimmunity would rapidly destroy transplanted SC ß-cells. A promising strategy to overcome immune rejection is to genetically engineer SC ß-cells. We previously identified Renalase (Rnls) as a novel target for ß-cell protection. Here we show that Rnls deletion endows ß-cells with the capacity to modulate the metabolism and function of immune cells within the local graft microenvironment. We used flow cytometry and single-cell RNA sequencing to characterize ß-cell graft-infiltrating immune cells in a mouse model for T1D. Loss of Rnls within transplanted ß-cells affected both the composition and the transcriptional profile of infiltrating immune cells in favor of an anti-inflammatory profile with decreased antigen-presenting capacity. We propose that changes in ß-cell metabolism mediate local immune regulation and that this feature could be exploited for therapeutic goals. ARTICLE HIGHLIGHTS: Protective Renalase (Rnls) deficiency impacts ß-cell metabolism. Rnls-deficient ß-cell grafts do not exclude immune infiltration. Rnls deficiency in transplanted ß-cells broadly modifies local immune function. Immune cell in Rnls mutant ß-cell grafts adopt a noninflammatory phenotype.